Combined administration of Spondias mombin and Ficus exasperata leaf extracts stall Indomethacin-mediated gastric mucosal onslaught in rats.

Background: Despite the rapidly changing concept of gastric ulcer management from conventional vagotomy, H2 receptor antagonists and antacids to proton pump inhibitors, gastrointestinal toxicity remains an impediment to their application in clinical practice. Combined administration of two or more plant extracts with therapeutic efficacy may proffer solution to this menace. This study investigated the combined gastroprotective effects of Spondias mombin and Ficus exasperata leaf extracts against indomethacin-induced gastric ulcer in rats.Materials and Methods: Thirty rats were randomized into six groups of five animals each and ulceration was induced by a single oral administration of indomethacin (30 mg/kg body weight). Ulcerated rats were orally administered with Spondias mombin, Ficus exasperata at 200 mg/kg body weightand esomeprazole (a reference drug) at a dose of 20 mg/kg body  weight once daily for 21 days after ulcer induction. At the end of the experiment, gastric secretions and antioxidant parameters were evaluated.Results: We observed that the significantly increased (P < 0.05) ulcer index, gastric acidity, malondialdehyde level and pepsin activity were markedly reduced following co-administration of S. mombin and F. exasperata. The extracts also effectively attenuated the reduced activities of superoxide dismutase and catalase as well as pH, mucin content and reduced glutathione level in the ulcerated rats.Discussion and Conclusion: These findings are indicative of gastroprotective and antioxidative attributes of the two extracts which is also evident in the % protective index value obtained. The available evidences in this study suggest that the complementary effects of S. mombin and F. exasperata proved to be capable of ameliorating indomethacin-mediated gastric ulceration and the probable mechanisms are via antioxidative and proton pump inhibition.Key words: Esomeprazole; Gastroprotective; NSAIDS; Proton pump inhibitor; Ulceration

Roadmap on energy harvesting materials

Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere

Wirelessly powered large-area electronics for the Internet of Things

Powering the increasing number of sensor nodes used in the Internet of Things creates a technological challenge. The economic and sustainability issues of battery-powered devices mean that wirelessly powered operation—combined with environmentally friendly circuit technologies—will be needed. Large-area electronics—which can be based on organic semiconductors, amorphous metal oxide semiconductors, semiconducting carbon nanotubes and two-dimensional semiconductors—could provide a solution. Here we examine the potential of large-area electronics technology in the development of sustainable, wirelessly powered Internet of Things sensor nodes. We provide a system-level analysis of wirelessly powered sensor nodes, identifying the constraints faced by such devices and highlighting promising architectures and design approaches. We then explore the use of large-area electronics technology in wirelessly powered Internet of Things sensor nodes, with a focus on low-power transistor circuits for digital processing and signal amplification, as well as high-speed diodes and printed antennas for data communication and radiofrequency energy harvesting

Roadmap on energy harvesting materials

Abstract Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere

Roadmap on energy harvesting materials

Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere.M C thanks the Centre Québécois sur les Matériaux Fonctionnels (CQMF, a Fonds de recherche du Québec – Nature et Technologies strategic network) and A L thanks the Canada Research Chairs program for financial support. G C W thanks the University of Calgary. This work was authored in part by the National Renewable Energy Laboratory, operated by Alliance for Sustainable Energy, LLC, for the U.S. Department of Energy (DOE) under Contract No. DE-AC36-08GO28308 with writing support for BWL by ARPA-E DIFFERENTIATE program under Grant No. DE-AR0001215. The views expressed in the article do not necessarily represent the views of the DOE or the U.S. Government.Peer reviewe

Roadmap on energy harvesting materials

Funder: Fundação para a Ciência e TecnologiaFunder: BIDEKO ProjectFunder: MCIN/AEIFunder: Spanish State Research Agency (AEI)Funder: Basic Science Research ProgramFunder: Ministry of Education; doi: http://dx.doi.org/10.13039/501100002701Funder: Swedish Knowledge FoundationFunder: University of Calgary; doi: http://dx.doi.org/10.13039/100008459Funder: National Renewable Energy Laboratory; doi: http://dx.doi.org/10.13039/100006233Funder: Fonds de recherche du Québec – Nature et technologies; doi: http://dx.doi.org/10.13039/501100003151Funder: Canada Research Chairs programFunder: EUFunder: National Research Foundation of Korea; doi: http://dx.doi.org/10.13039/501100003725Funder: NRFFunder: Priority Research Centers ProgramFunder: European regional development fund (ERDF)Funder: European Research Council (ERC)Funder: ERCFunder: Alliance for Sustainable Energy, LLCFunder: MIURFunder: Italian MinistryFunder: the Cardiff University, Engineering and Physical Sciences Research CouncilFunder: JST Mirai ProgramFunder: Agence Nationale de la Recherche (ANR)Funder: A*STARFunder: JSTFunder: PRESTOFunder: Aerospace ProgrammeFunder: EBFunder: U.S. Department of Commerce, National Institute of Standards and TechnologyFunder: Laboratory-Directed Research and Development (LDRD)Funder: Sandia, LLCFunder: the Office of Science, Office of Basic Energy SciencesFunder: United States GovernmentFunder: Honeywell International Inc.Funder: The Leverhulme TrustFunder: Royal Academy of Engineering; doi: http://dx.doi.org/10.13039/501100000287Funder: Office of the Chief Science Adviser for National SecurityFunder: Henry Samueli School of Engineering & Applied ScienceFunder: Department of Bioengineering at the University of California, Los AngelesFunder: CRESTFunder: Beijing Forestry University; doi: http://dx.doi.org/10.13039/501100012138Funder: Japan Science and Technology Agency (JST)Funder: the Australian Research Council, QUTFunder: Center for Hierarchical Materials DesignFunder: Austrian Christian Doppler Laboratory for ThermoelectricityFunder: HBIS-UQ Innovation Centre for Sustainable SteelAmbient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere

Roadmap on energy harvesting materials

Funder: Fundação para a Ciência e TecnologiaFunder: BIDEKO ProjectFunder: MCIN/AEIFunder: Spanish State Research Agency (AEI)Funder: Basic Science Research ProgramFunder: Ministry of Education; doi: http://dx.doi.org/10.13039/501100002701Funder: Swedish Knowledge FoundationFunder: University of Calgary; doi: http://dx.doi.org/10.13039/100008459Funder: National Renewable Energy Laboratory; doi: http://dx.doi.org/10.13039/100006233Funder: Fonds de recherche du Québec – Nature et technologies; doi: http://dx.doi.org/10.13039/501100003151Funder: Canada Research Chairs programFunder: EUFunder: National Research Foundation of Korea; doi: http://dx.doi.org/10.13039/501100003725Funder: NRFFunder: Priority Research Centers ProgramFunder: European regional development fund (ERDF)Funder: European Research Council (ERC)Funder: ERCFunder: Alliance for Sustainable Energy, LLCFunder: MIURFunder: Italian MinistryFunder: the Cardiff University, Engineering and Physical Sciences Research CouncilFunder: JST Mirai ProgramFunder: Agence Nationale de la Recherche (ANR)Funder: A*STARFunder: JSTFunder: PRESTOFunder: Aerospace ProgrammeFunder: EBFunder: U.S. Department of Commerce, National Institute of Standards and TechnologyFunder: Laboratory-Directed Research and Development (LDRD)Funder: Sandia, LLCFunder: the Office of Science, Office of Basic Energy SciencesFunder: United States GovernmentFunder: Honeywell International Inc.Funder: The Leverhulme TrustFunder: Royal Academy of Engineering; doi: http://dx.doi.org/10.13039/501100000287Funder: Office of the Chief Science Adviser for National SecurityFunder: Henry Samueli School of Engineering & Applied ScienceFunder: Department of Bioengineering at the University of California, Los AngelesFunder: CRESTFunder: Beijing Forestry University; doi: http://dx.doi.org/10.13039/501100012138Funder: Japan Science and Technology Agency (JST)Funder: the Australian Research Council, QUTFunder: Center for Hierarchical Materials DesignFunder: Austrian Christian Doppler Laboratory for ThermoelectricityFunder: HBIS-UQ Innovation Centre for Sustainable SteelAbstract Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere.</jats:p

Dominant modifiable risk factors for stroke in Ghana and Nigeria (SIREN): a case-control study

Summary: Background: Sub-Saharan Africa has the highest incidence, prevalence, and fatality from stroke globally. Yet, only little information about context-specific risk factors for prioritising interventions to reduce the stroke burden in sub-Saharan Africa is available. We aimed to identify and characterise the effect of the top modifiable risk factors for stroke in sub-Saharan Africa. Methods: The Stroke Investigative Research and Educational Network (SIREN) study is a multicentre, case-control study done at 15 sites in Nigeria and Ghana. Cases were adults (aged ≥18 years) with stroke confirmed by CT or MRI. Controls were age-matched and gender-matched stroke-free adults (aged ≥18 years) recruited from the communities in catchment areas of cases. Comprehensive assessment for vascular, lifestyle, and psychosocial factors was done using standard instruments. We used conditional logistic regression to estimate odds ratios (ORs) and population-attributable risks (PARs) with 95% CIs. Findings: Between Aug 28, 2014, and June 15, 2017, we enrolled 2118 case-control pairs (1192 [56%] men) with mean ages of 59·0 years (SD 13·8) for cases and 57·8 years (13·7) for controls. 1430 (68%) had ischaemic stoke, 682 (32%) had haemorrhagic stroke, and six (<1%) had discrete ischaemic and haemorrhagic lesions. 98·2% (95% CI 97·2–99·0) of adjusted PAR of stroke was associated with 11 potentially modifiable risk factors with ORs and PARs in descending order of PAR of 19·36 (95% CI 12·11–30·93) and 90·8% (95% CI 87·9–93·7) for hypertension, 1·85 (1·44–2·38) and 35·8% (25·3–46·2) for dyslipidaemia, 1·59 (1·19–2·13) and 31·1% (13·3–48·9) for regular meat consumption, 1·48 (1·13–1·94) and 26·5% (12·9–40·2) for elevated waist-to-hip ratio, 2·58 (1·98–3·37) and 22·1% (17·8–26·4) for diabetes, 2·43 (1·81–3·26) and 18·2% (14·1–22·3) for low green leafy vegetable consumption, 1·89 (1·40–2·54) and 11·6% (6·6–16·7) for stress, 2·14 (1·34–3·43) and 5·3% (3·3–7·3) for added salt at the table, 1·65 (1·09–2·49) and 4·3% (0·6–7·9) for cardiac disease, 2·13 (1·12–4·05) and 2·4% (0·7–4·1) for physical inactivity, and 4·42 (1·75–11·16) and 2·3% (1·5–3·1) for current cigarette smoking. Ten of these factors were associated with ischaemic stroke and six with haemorrhagic stroke occurrence. Interpretation: Implementation of interventions targeting these leading risk factors at the population level should substantially curtail the burden of stroke among Africans. Funding: National Institutes of Health